The aim of this study was to compare the in vitro wear and superficial roughness of four materials (Delton Dyract Flow, Dentsply; Filtek Flow, Vitremer, 3M ESPE) used as fissure sealant in 32 extracted human molars divided in four groups (n = 8) after abrasion with toothbrush/dentifrice. Impressions of each occlusal surface were made to analyze wear and circular specimens were prepared to analyze the roughness. Teeth and specimens were mounted in a toothbrushing machine. The replicas were observed using a SEM to determine the superficial wear. Wear: there were no statistically significant differences either between Delton and Filtek Flow or between Dyract Flow and Vitremer. Roughness: there were no statistical differences between Filtek Flow and Dyract Flow, Dyract Flow and Vitremer, Vitremer and Delton., Considering the clinical practice, if caries activity is present the use of Vitremer is suggested not only for its well known fluoride release, but it presented good roughness results.

In the past years, there has been an observable decrease in caries incidence1,2. However, this disease concentrates on occlusal surfaces that are responsible for about 56 to 70% of the caries in children of 517 years of age3,4. A large number of studies have shown that the use of fissure sealant is efficient in preventing caries on these surfaces5.

Many materials have been developed for fissure sealing. However, some materials used to fill teeth can also be used as fissure sealant, i.e. flowable composite or flowable polyacidmodified resin composite a common material that most of the dentists have in their office. Some resin modified glass ionomers (RMGI) have been applied as fissure sealant610, although their manufacturer does not indicate them for this use. The advantage of the RMGI as well as glass ionomer cements is that they release fluoride11,12 that influences the demineralization and remineralization process13.

The retention and effectiveness of different materials applied as fissure sealant have been studied in vivo. However, dentists are unwilling to use this procedure in their clinical practice. Two of the main reasons cited are the low retention and high wear rates of these materials14.

The wear rate of a great number of restorative materials have been studied, nevertheless there are few studies about wear of different materials used as fissure sealant. This property is important since sealant is an extra coronal addition to the occlusal surface and its wear characteristics might be a little different from those that are found in restorative materials that are placed in cavities14.

Dental materials, restorative or fissure sealants, are directly affected by oral cavity conditions, such as saliva, foods, tooth brushing and chewing forces15. Laboratory studies are useful in providing information on fundamental wear mechanisms; however devices used in wear tests simulate one or two of the wear mechanisms that simultaneously occur in the mouth16. According to Morgan (2004)17 the development of an optimal surface polish reduces stain and plaque accumulation and minimizes wear.

The aim of this study was to compare the in vitro wear and roughness of different materials used as fissure sealant after abrasion with toothbrush and dentifrice . Considering the importance of tooth brushing to the maintenance of the oral health, the tested hypothesis in this experiment was that the resinbased materials would present the best results regarding wear and roughness after exposure to an abrasive wear test.

2. Materials and Methods

The project was submitted and approved by the Ethics Committee of the Dentistry College  University of Campinas (#042/2002).

Thirtytwo extracted human third molars without filling, evidence of caries or cracks were stored in distilled water after extraction. Following this, they were cleaned using periodontal instruments and pumice prophylaxis. Then, the teeth were maintained in distilled water at 4 °C. The teeth were randomly distributed in the following groups: DeDelton; FFFiltek Flow; DFDyract Flow and VitVitremer.

The sealants were applied after pumice prophylaxis of the occlusal surfaces and etching of the teeth with 37% phosphoric acid gel (Dentsply De Trey) for 15 seconds. Then, the teeth were rinsed with a spray of air/water. The sealants were applied according to the manufacturer instructions, with exception of Vitremer that was mixed in a powder / liquid proportion of 1:2, to obtain lower viscosity so that the mixture flows into the fissures8.

Impressions of each tooth were made using addition silicone (Aquasil  Dentsply De Trey) and filled with epoxy resin (Epoxide  BÜHLER, Lake Bluff, IL, USA) after the placement of the materials. The teeth were stored at 37 °C at 100% relative humidity until the preparation with the tooth brushing machine.

2.2. Roughness evaluation

Eight circular specimens (3 mm in height and 5 mm in diameter) of each material were fabricated in an addition silicone mold to verify the roughness of the materials before and after the abrasion test. The instructions of the manufacturers were followed for handling the materials, except for Vitremer, which was prepared in a proportion of 1:2 powder/liquid8. The molds were filled with the material, covered with a polyester strip and a thin glass slab and when necessary, the specimens were lightcured (Photo Unit XL 1500  3M/ESPE  St Paul, MN, USA) following the exposure time recommended by the manufacturer. Then, the specimens were polished with sandpaper (600, 1000 and 1200 grain), and were stored at 37 °C at 100% relative humidity until the abrasion test.

The initial roughness measurement of the specimens was carried out using a Profilometer (SurfCorder SE 1700  Kosaka Lab, Tokyo, Japan). Before the measuring, each specimen was gently dried with absorbent paper and air. The cutoff value was set at 0.25 mm and the surface roughness was characterized by the average roughness (Ra). The Ra value was used because it represents the arithmetical average value of all absolute distances of the roughness profile from the center line within the measuring length18. Three readings were made on each surface using a stylus tip, which has a diameter of 2 µm. Each reading was obtained after turning the specimen 120°. The measurements were carried out before and after the abrasion test.

Infantile toothbrushes with soft nylon bristles (Colgate® Classic Infantil  Kolynos® do Brasil, Ltda., Osasco, SP, Brazil) were used. The head was sectioned with a tungsten carbide bur and fixed in the toothbrush holder device of the machine using Super Bonder® (Loctite®, SP, Brazil) fast setting adhesive. The samples were fixed on a plastic plate. The toothbrush was fixed perpendicular to the specimen surface. The test was made under a load of 200 g, which was used to simulate the load of oral hygiene procedures.

Specimens were brushed in the presence of a dentifrice containing calcium carbonate (mean 6.5 µm) as an abrasive (Sorriso®  Colgate® Classic Infantil  Kolynos® do Brasil, Ltda., Osasco, SP, Brazil) mixed with distilled water at a ratio of 1:1 in weight. The dentifrice was weighed on a precision balance. The specimens were subjected to linear tooth brushing movements across the specimens, at a speed of 250 cycles/minute, considering a double pass of the brush head over the surface, for 2 hours, totaling 30,000 cycles per specimen. This number of cycles corresponds to approximately 2 years of tooth brushing19. After the test, the specimens were removed, rinsed with tap water and stored at 37 °C at 100% relative humidity.

2.4. Analysis of wear

The sealed teeth were molded again as previously described. All the replicas in epoxy resin were observed in a scanning electron microscopy (SEM  LEO VP 435, Cambridge, United Kingdom) (x18) to evaluate the wear by comparison between the first and the second models. The area of assessment was the whole occlusal surface. The scores were: 0  no change in the sealant surface; 1) polishing of the sealant surface without changes in the border; 2) polishing of the sealant surface with changes in the border and 3) sealant loss in some pit or fissure. Two examiners who were previously calibrated observed the images. They were blinded to the specimens. At this step the examiners observed different images of fissure sealant SEMs and discussed them until they reached an agreement.

2.5. Statistical analysis

The sample size was calculated considering a mean of roughness of 0.30, a standard deviation of 0.04, an αlevel of 0.05 and a test power of 0.90. To observe a minimum difference of 2% it was considered necessary 8 specimens for each group in a total of 32 specimens.

The results of surface roughness were analyzed with repeatedmeasures analysis of variance, followed by the Tukey Test at the level of 5% significance. Differences among the wear of the materials after the tooth brushing was analyzed using a KruskalWallis with a Dunn multiple comparison test. The Kappa Test was employed to verify the interexaminer reproducibility and the intraclass correlation coefficient to verify the intraexaminer reproducibility in regard to the wear evaluation.

3. Results

The wear of the models was evaluated by 2 examiners and the interexaminer reproducibility was 0.85, while the intraexaminer was higher than 0.90.

The median and the mean rank of the wear of the materials can be observed in Table 1. There were no statistically significant differences either between materials De and FF or between materials DF and Vit with the former showing the lower wear.

The mean roughness of the 4 materials, before and after the abrasion test, can be observed in Table 2. Statistically significant differences among materials FF, DF and Vit were not verified; De showed the roughest surface. After tooth brushing FF presented the highest roughness measurement and De and Vit, the lowest. For each material, statistical differences were observed for roughness before and after the test which can be observed in Table 2. Delton demonstrated lower roughness after the abrasion test than before the test, which was the opposite of the other materials studied.

4. Discussion

Although fissure sealants have been considered effective in preventing occlusal caries20 and a great number of clinical studies about this procedure have been published, there are few studies about the wear resistance and the roughness of the different materials used as fissure sealants.

In the present study, four different types of dental materials were submitted to an abrasion test with toothbrush and dentifrice in vitro. Regarding wear, the sealed teeth with Vitremer and Dyract Flow showed the highest wear and there was no statistically significant difference between them. Vitremer is a resin modified glass ionomer (RMGI) and most of its physical properties are inferior to those of resinbased materials15,17. Vitremer and Dyract Flow are hybrid materials and contain variable quantity of resin in their structures, which are not exclusively polymerics. This explains why these materials have presented higher wear than Filtek Flow and Delton. According to Momoi et al., 199722 this material is less abrasion resistant because of the lower surface hardness. ElKalla & GarcíaGodoy, 199923 studied mechanical properties of compomers and suggested that compomer restorative material be placed between RMGI and composite in their study, since the tested materials "displayed the same arrangement of strength in both stages of the threepoint bending test, the yield and flexural strength". However, Braem et al., 199524, concluded that the strength and flexural fatigue values of compomers are similar to the composites; a fact that could justify their use as a substitute for composites.

Wear is the least understood property of the restorative materials, since it involves different processes that can interact with each other22. For this reason, in the present study only the abrasion with dentifrice and toothbrush was evaluated. The in vivo results probably differ since the fissure sealant is also affected by saliva, food and masticatory forces15.

There was no statistically significant difference between Delton and Filtek Flow in regards to wear in the present study. These materials are polymeric structures and the most important difference between them is the filler presence. Theoretically, unfilled materials demonstrate more wear than filled materials25 but in the present study differences between them were not observed. This result may have occured because in the mechanical tooth brushing machine the filler is not the main element that offers the wear resistance. The matrix may be more important in this case. Lugassy & Greener (1972)26 showed that the pattern of wear is different between an unfilled resin and a filled resin. According to them, the abrasion of an unfilled resin is lower and the wear is more uniform than that of a filled one.

Regarding roughness, Delton showed lower roughness measurement after tooth brushing than before the abrasion test. This fact confirms that the wear of an unfilled resin is more uniform than that of a filled resin26, since the roughness measurement of Filtek Flow increased after the test. The slurry used in this study had calcium carbonate as abrasive; particles of the filled resin detach and can act as an additional abrasive agent themselves, increasing the abrasion of the slurry27. Besides this, wear of the resin matrix allows particles of the filled resin to protrude and make the surface more irregular. This can explain the higher roughness of the Filtek Flow material after the abrasion test. In contrast, as Delton is an unfilled resin, it presented a lower roughness after this test.

There were no statistically significant differences amongst Filtek Flow, Dyract Flow and Vitremer regarding roughness before the test. According to ElKalla & GarcíaGodoy, 199923 handmixing materials do not produce the same surface as materials that are in paste form, such as composites and compomers. The low ratio of powder:liquid decreases the glass particles, which increases their susceptibility to erosion28. In addition, the high roughness measurement to Vitremer can be a result of porosity caused by air bubbles in the material setting or by the particles exposed during abrasion29. The good results observed for this material before and after the abrasion test regarding roughness can be explained by the fact that this material is covered with a resinbased material (Finishing Gloss) after its setting.

Most clinical studies show that the resinbased material has the best retention rates19,3033 in comparison to PMRC, RMGI and glass ionomer cement (GIC) when these materials are applied as fissure sealants. In vitro studies are useful to explain some conditions, of materials separate from when they are exposed in the mouth. Therefore, the results cannot be extrapolated to the clinical practice, since, as previously explained, several factors are acting on the dental materials at the same time. In the clinical practice, teeth with incipient caries or those that are not totally erupted in patients with caries activity should receive fissure sealant. In these cases, ionomeric materials (GIC and RMGI) are indicated for this treatment, since their capability of fluoride releasing is known. Even though a dental material releases fluoride, its surface should be sufficiently smooth in order to not accumulate substrate and microorganisms34. The Vitremer material showed good results regarding roughness in the present study.

With the methodology employed in this study, it was verified that between the modified materials Vitremer and Dyract Flow similar wear was observed as well as between Filtek Flow and Delton, however the wear of the former was higher. Vitremer and Delton showed lower roughness measurements after the abrasion test. . Considering the clinical situation, when caries activity is present the use of Vitremer is suggested as a fissure sealant, besides its well known fluoride release, in the present study along with Delton, it presented low roughness.

Acknowledgements

This study was supported by a grant from FAPESP  #02/001566. The authors express their gratitude to Marcos Blanco Cangiani, technician of Dental Materials laboratory of the Dentistry College, UNICAMP, Piracicaba, Brazil. We are grateful to Thomas W. Brown III for his editorial assistance and proofreading for correct English.

References

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